Your search keyword '"Yiu, Joycelyn"' showing total 3 results

1. Exploring the advantages of intensity-modulated proton therapy: experimental validation of biological effects using two different beam intensity-modulation patterns.

Author

Ma, Duo, Bronk, Lawrence, Kerr, Matthew, Sobieski, Mary, Chen, Mei, Geng, Changran, Yiu, Joycelyn, Wang, Xiaochun, Sahoo, Narayan, Cao, Wenhua, Zhang, Xiaodong, Stephan, Clifford, Mohan, Radhe, Grosshans, David R., and Guan, Fada

Abstract

In current treatment plans of intensity-modulated proton therapy, high-energy beams are usually assigned larger weights than low-energy beams. Using this form of beam delivery strategy cannot effectively use the biological advantages of low-energy and high-linear energy transfer (LET) protons present within the Bragg peak. However, the planning optimizer can be adjusted to alter the intensity of each beamlet, thus maintaining an identical target dose while increasing the weights of low-energy beams to elevate the LET therein. The objective of this study was to experimentally validate the enhanced biological effects using a novel beam delivery strategy with elevated LET. We used Monte Carlo and optimization algorithms to generate two different intensity-modulation patterns, namely to form a downslope and a flat dose field in the target. We spatially mapped the biological effects using high-content automated assays by employing an upgraded biophysical system with improved accuracy and precision of collected data. In vitro results in cancer cells show that using two opposed downslope fields results in a more biologically effective dose, which may have the clinical potential to increase the therapeutic index of proton therapy. [ABSTRACT FROM AUTHOR]

Published

2020

2. Mapping the Relative Biological Effectiveness of Proton, Helium and Carbon Ions with High-Throughput Techniques.

Author

Bronk, Lawrence, Guan, Fada, Patel, Darshana, Ma, Duo, Kroger, Benjamin, Wang, Xiaochun, Tran, Kevin, Yiu, Joycelyn, Stephan, Clifford, Debus, Jürgen, Abdollahi, Amir, Jäkel, Oliver, Mohan, Radhe, Titt, Uwe, and Grosshans, David R.

Subjects

BIOPHYSICS, CARBON, CELL lines, ENERGY transfer, HELIUM, IONS, LUNG tumors, PROTONS, RADIATION doses, RADIOBIOLOGY, SURVIVAL, SYSTEM analysis, X-rays, PROTON therapy

Abstract

Simple Summary: Although particle therapy using protons and heavier ions has many inherent advantages when compared to x-rays for cancer treatment, numerous unknowns still exist in the radiobiology of particle therapy. Informative high-accuracy biological effects data are lacking and difficult to obtain. This study aimed to provide a novel high-throughput experimental method to more efficiently obtain large amounts of biophysical data of particle therapy and to correlate the biological responses with the physical characteristics of particle beams. Large amounts of high quality biophysical data are needed to improve current biological effects models but such data are lacking and difficult to obtain. The present study aimed to more efficiently measure the spatial distribution of relative biological effectiveness (RBE) of charged particle beams using a novel high-accuracy and high-throughput experimental platform. Clonogenic survival was selected as the biological endpoint for two lung cancer cell lines, H460 and H1437, irradiated with protons, carbon, and helium ions. Ion-specific multi-step microplate holders were fabricated such that each column of a 96-well microplate is spatially situated at a different location along a particle beam path. Dose, dose-averaged linear energy transfer (LETd), and dose-mean lineal energy (yd) were calculated using an experimentally validated Geant4-based Monte Carlo system. Cells were irradiated at the Heidelberg Ion Beam Therapy Center (HIT). The experimental results showed that the clonogenic survival curves of all tested ions were yd-dependent. Both helium and carbon ions achieved maximum RBEs within specific yd ranges before biological efficacy declined, indicating an overkill effect. For protons, no overkill was observed, but RBE increased distal to the Bragg peak. Measured RBE profiles strongly depend on the physical characteristics such as yd and are ion specific. [ABSTRACT FROM AUTHOR]

Published

2020

3. Author Correction: Exploring the advantages of intensity-modulated proton therapy: experimental validation of biological effects using two different beam intensity-modulation patterns.

Author

Ma, Duo, Bronk, Lawrence, Kerr, Matthew, Sobieski, Mary, Chen, Mei, Geng, Changran, Yiu, Joycelyn, Wang, Xiaochun, Sahoo, Narayan, Cao, Wenhua, Zhang, Xiaodong, Stephan, Clifford, Mohan, Radhe, Grosshans, David R., and Guan, Fada

Subjects

PROTON therapy, BEAM injection

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper. [ABSTRACT FROM AUTHOR]

Published

2020